Tabea Kohlfärber

Doktorandin


Institut für Biomedizinische Optik
Maria Göppert-Str.1
23562 Lübeck



Gebäude MFC1, Raum 411-2

Email:
Phone:
+49 (0)451 3101 3244
Fax:
+49 451 31013204




2021

  • Hinnerk Schulz-Hildebrandt and Martin Ahrens and Michael Münter and Elisa Wilken and Tabea Kohlfärber and Cornelia Holzhausen and Peter König and Gereon Hüttmann: Endo-microscopic optical coherence tomography (emOCT) with dynamic contrast. in Endoscopic Microscopy XVI, no. 11620, SPIE, 2021
    BibTeX Link Link
    @inproceedings{10.1117/12.2575733,
    
    title = {Endo-microscopic optical coherence tomography (emOCT) with dynamic contrast},
    
    author = {Hinnerk Schulz-Hildebrandt and Martin Ahrens and Michael M\"{u}nter and Elisa Wilken and Tabea Kohlf\"{a}rber and Cornelia Holzhausen and Peter K\"{o}nig and Gereon H\"{u}ttmann},
    
    editor = {Guillermo Tearney J M.D. and Thomas D Wang and Melissa J Suter},
    
    url = {https://doi.org/10.1117/12.2575733},
    
    doi = {10.1117/12.2575733},
    
    year  = {2021},
    
    date = {2021-01-01},
    
    booktitle = {Endoscopic Microscopy XVI},
    
    volume = {11620},
    
    publisher = {SPIE},
    
    organization = {International Society for Optics and Photonics},
    
    keywords = {},
    
    pubstate = {published},
    
    tppubtype = {inproceedings}
    
    }
    

2019

  • South,F A; Liu, Y-Z; Huang, P-C and Kohlfärber, T and Boppart, S A: Local wavefront mapping in tissue using computational adaptive optics OCT. Opt Lett 44(5), pp. 1186-1189, OSA, 2019
    BibTeX Link
    @article{South:19,
    author = { South,F A; Liu, Y-Z; Huang, P-C and Kohlfärber, T and Boppart, S A},
    journal = { Opt Lett 44(5)}
    pages = {1186--1189},
    keywords = {Adaptive optics; Image metrics; Image quality; Refractive index; Speckle noise; Wavefront aberrations},
    number = {5},
     
    publisher = {OSA},
    title = {Local wavefront mapping in tissue using computational adaptive optics OCT},
    
    
    year = {2019},
    doi = {10.1364/OL.44.001186},
    abstract = {The identification and correction of wavefront aberrations is often necessary to achieve high-resolution optical images of biological tissues, as imperfections in the optical system and the tissue itself distort the imaging beam. Measuring the localized wavefront aberration provides information on where the beam is distorted and how severely. We have recently developed a method to estimate the single-pass wavefront aberrations from complex optical coherence tomography (OCT) data. Using this method, localized wavefront measurement and correction using computational OCT was performed in ex vivo tissues. The computationally measured wavefront varied throughout the imaged OCT volumes and, therefore, a local wavefront correction outperformed a global wavefront correction. The local wavefront measurement was also used to generate tissue aberration maps. Such aberration maps could potentially be used as a new form of tissue contrast.},
    }